Global connectivity and function of descending spinal input revealed by 3D microscopy and retrograde transduction

Wang, Zimei; Maunze, Brian; Tsoulfas, Pantelis; Blackmore, Murray G.

doi:10.1101/314237

Cited by 20 publications

(49 citation statements)

References 40 publications

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“…This result is in contrast to the suggestion that for cortically-dependent movements motor commands are conveyed primarily via PT neurons 5,16 . However, our observations are consistent with key roles for subcortical structures such as basal ganglia in the regulation of movement vigor 39,59 , critical functions for extrapyramidal motor pathways in regulating movement execution 60 , and the notion that corticospinal projections are primarily recruited for fine control of dexterity 2,61 rather than gross movement 59 . Our data together with previous work provide evidence that the relative recruitment of IT and PT neuron types is task specific and reflects a flexible routing of motor cortical output through downstream effectors 17 .…”

Section: Discussionsupporting

confidence: 84%

Motor cortical output for skilled forelimb movement is selectively distributed across projection neuron classes

Park

Phillips

Martin

et al. 2019

Preprint

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Motor cortex is part of a network of central brain circuits that together enable robust, flexible, and efficient movement in mammals. Recent work has revealed rich dynamics in mammalian motor cortex 1-7 thought to underlie robust and flexible movements. These dynamics are a consequence of recurrent connectivity between individual cortical neuron subtypes 8 , but it remains unclear how such complex dynamics relate to individual cell types and how they covary with continuous behavioral features. We investigated this in mice, combining a selfpaced, kinematically-variable, cortex-dependent, bimanual motor task 9,10 with large-scale neural recordings that included cell-type information. This revealed highly distributed correlates of movement execution across all layers of forelimb motor cortex and subcortical areas. However, we observed a surprising relative lack of modulation in the putative source of motor commands brain-stem projecting (pyramidal tract, PT) neurons 11 . By contrast, striatal/cortical projecting (intratelencephalic, IT) neurons showed much stronger correlations with movement kinematics. Cell-type specific inactivation of PT neurons during movement execution had little effect on behavior whereas inactivation of IT neurons produced dramatic decreases in the speed and amplitude of forelimb movements. PT inactivation elicited rapid, compensatory changes in activity distributed across multiple cortical layers and subcortical regions helping to explain minimal effects of inactivation on behavior. This work illustrates how cortical-striatal population dynamics play a critical role in the control of movement while maintaining substantial flexibility in the extent to which PT projection neurons are a requisite contributor to descending motor commands. † equal contribution FIGURE 1 Distributed task related neural dynamics in a self-initiated variable amplitude operant taskA) Mice were trained to perform an self-initiated (uncued) vigor-control task, in which movements were made for delayed reward (left). To perform this, mice were head-fixed, and moved a joystick bimanually (middle). Recordings were made in forelimb motor cortex and striatum with a neuropixels 3A probe, which densely sampled neural activity in the depth axis (right, see inset for recording site spacing). B) Mice adjusted their reach amplitude across the three blocks. Left plot shows data from a single session, right plot shows the data across sessions. See main text for statistics. C) Population neural activity showed two peaks, one around reach and one around reward. Mean population activity relative to joystick velocity (thresholded to only show outward) and lick rate. Mean activity of units was taken for units above 1600um depth (cortical units) and those below 1800um depth (striatal units), then binned into 50ms bins, and each resulting array was normalized to the range 0-1. D) Many units were tuned to movement kinematics. Two example units (left and middle) show tuning of neural activity to each tertile of reach amplitudes. Right figure ...

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Section: Discussionsupporting

confidence: 84%

Motor cortical output for skilled forelimb movement is selectively distributed across projection neuron classes

Park

Phillips

Martin

et al. 2019

Preprint

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“…When analysing the output of S1-CST neurons, we found evidence that, although they mainly project through the CST onto the spinal dorsal horn, they also send collateral branches to the dorsal striatum and the midbrain. This confirms and further specifies previous experiments in which CST collaterals were observed when all spinally projecting neurons were labelled Wang Z et al 2018). Our data therefore indicate that while their main target is the spinal dorsal horn, S1-CST neurons also contribute to cortico-striatal projections and may thereby influence goal-directed behaviours .…”

Section: S1-cst Neurons In Somatosensory Circuitssupporting

confidence: 92%

“…To this end, it would be crucial to restrict transgene expression to the layer 5 pyramidal neurons in an area of the cortex (S1 in this case) that projects to the spinal region of interest such as the dorsal horn of the spinal cord. Recently, a new recombinant adeno-associated virus (rAAV) serotype (rAAV2-retro) (Tervo DG et al 2016) has been developed with greatly improved retrograde labelling efficiency that allows high fidelity tracing of descending inputs to the spinal cord (Haenraets K et al 2017;Wang Z et al 2018).…”

Section: Introductionmentioning

confidence: 99%

In-depth characterization of layer 5 output neurons of the primary somatosensory cortex innervating the mouse dorsal spinal cord

Frezel

Mateos

Platonova

et al. 2020

Preprint

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Neuronal circuits of the spinal dorsal horn integrate sensory information from the periphery with inhibitory and facilitating input from higher CNS areas. Most previous work focused on descending projections originating from the hindbrain. Less is known about the organisation of inputs descending from the cerebral cortex. Here, we identified cholecystokinin (CCK) positive layer 5 pyramidal neurons of the primary somatosensory cortex (S1-CST neurons) as a major source of descending input to the spinal dorsal horn. We combined intersectional genetics and virus-mediated gene transfer to characterize CCK + S1-CST neurons and to define their presynaptic input and postsynaptic target neurons. We found that S1-CST neurons constitute a heterogeneous population that can be subdivided into distinct molecular subgroups. Rabies-based retrograde tracing revealed monosynaptic input from layer 2/3 pyramidal neurons, from parvalbumin (PV) and neuropeptide Y (NPY) positive cortical interneurons, and from thalamic relay neurons in the ventral posterolateral nucleus. WGA-based anterograde tracing identified postsynaptic target neurons in dorsal horn laminae III and IV. About 60% of these neurons were inhibitory and about 60% of all spinal target neurons expressed the transcription factor c-Maf. The heterogeneous nature of both S1-CST neurons and their spinal targets suggest sophisticated roles in the fine-tuning of sensory processing.Research University (PSL), Paris 75005, France. E. Platonova has been supported through the Technology Platform commission of the University of Zürich. We want to thank C. Kaiser for the technical support and F. Voigt and F. Helmchen for the support with the MesoSPIM.

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“…Finally, a key finding was that delivery of KLF6 by retrograde vectors, but not direct cranial injection, improved forelimb function after spinal injury. We recently characterized retrograde transduction after spinal injections of AAV2-Retro, and showed widespread transduction of CST neurons throughout the cortex, in addition to subcortical nuclei that participate in skilled movements, including the red nucleus and reticular formation (29). The likely explanation for the difference in behavioral outcomes is that compared to focal delivery to subregions of motor cortex, retrograde vectors deliver therapeutic transgenes to a larger number and greater diversity of supraspinal cell types.…”

Section: Discussionmentioning

confidence: 99%

“…To deliver KLF6 more broadly we employed Retro-AAV, a newly developed vector with enhanced retrograde properties. We recently showed that delivery of Retro-AAV to the cervical spinal cord produces highly efficient transduction of CST neurons throughout the cortex, in addition to subcortical populations including the rubrospinal tract (29). To confirm the ability of Retro-AAV to drive KLF6 expression we co-injected Retro-AAV2-KLF6 and Retro-AAV2-tdTomato to cervical spinal cord.…”

Section: Retrograde Klf6 Delivery and Npc Grafting Promote Forelimb Fmentioning

confidence: 99%

Restoration of Direct Corticospinal Communication Across Sites of Spinal Injury

Jayaprakash

Nowak

Eastwood

et al. 2019

Preprint

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Injury to the spinal cord often disrupts long-distance axon tracts that link the brain and spinal cord, causing permanent disability. Axon regeneration is then prevented by a combination of inhibitory signals that emerge at the injury site and by a low capacity for regeneration within injured neurons. The corticospinal tract (CST) is essential for fine motor control but has proven refractory to many attempted pro-regenerative treatments. Although strategies are emerging to create relay or detour circuits that reroute cortical motor commands through spared circuits, these have only partially met the challenge of restoring motor control. Here, using a murine model of spinal injury, we elevated the intrinsic regenerative ability of CST neurons by supplying a pro-regenerative transcription factor, KLF6, while simultaneously supplying injured CST axons with a growth-permissive graft of neural progenitor cells (NPCs) transplanted into a site of spinal injury. The combined treatment produced robust CST regeneration directly through the grafts and into distal spinal cord. Moreover, selective optogenetic stimulation of regenerated CST axons and single-unit electrophysiology revealed extensive synaptic integration by CST axons with spinal neurons beyond the injury site. Finally, when KLF6 was delivered to injured neurons with a highly effective retrograde vector, combined KLF6/NPC treatment yielded significant improvements in forelimb function. These findings highlight the utility of retrograde gene therapy as a strategy to treat CNS injury and establish conditions that restore functional CST communication across a site of spinal injury. Significance StatementDamage to the spinal cord results in incurable paralysis because axons that carry descending motor commands are unable to regenerate. Here we deployed a two-pronged strategy in a rodent model of spinal injury to promote regeneration by the corticospinal tract, a critical mediator of fine motor control. Delivering pro-regenerative KLF6 to injured neurons while simultaneously transplanting neural progenitor cells to injury sites resulted in robust regeneration directly through sites of spinal injury, accompanied by extensive synapse formation with spinal neurons. In addition, when KLF6 was delivered with improved retrograde gene therapy vectors, the combined treatment significantly improved forelimb function in injured animals. This work represents important progress toward restoring regeneration and motor function after spinal injury.

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Global connectivity and function of descending spinal input revealed by 3D microscopy and retrograde transduction

Cited by 20 publications

References 40 publications

Motor cortical output for skilled forelimb movement is selectively distributed across projection neuron classes

Motor cortical output for skilled forelimb movement is selectively distributed across projection neuron classes

In-depth characterization of layer 5 output neurons of the primary somatosensory cortex innervating the mouse dorsal spinal cord

Restoration of Direct Corticospinal Communication Across Sites of Spinal Injury

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